Home Search Collections Journals About Contact us My IOPscience Unidirectional surface plasmons in nonreciprocal graphene This content has been downloaded from IOPscience. Please scroll down to see the full text. 2013 New J. Phys. 15 113003 (http://iopscience.iop.org/1367-2630/15/11/113003) View the table of contents for this issue, or go to the journal homepage for more Download details: IP Address: 129.11.21.2 This content was downloaded on 17/05/2015 at 16:08 Please note that terms and conditions apply. Unidirectional surface plasmons in nonreciprocal graphene Xiao Lin1,2,3,4, Yang Xu2,4,6, Baile Zhang3,5, Ran Hao2, Hongsheng Chen1,2,3,4,6 and Erping Li2 1 State Key Laboratory of Modern Optical Instrumentation, Zhejiang University, Hangzhou 310027, People’s Republic of China 2 Department of Information Science and Electronic Engineering, Zhejiang University, Hangzhou 310027, People’s Republic of China 3 The Electromagnetics Academy at Zhejiang University, Zhejiang University, Hangzhou 310027, People’s Republic of China 4 Cyrus Tang Center for Sensor Materials and Applications, Zhejiang University, Hangzhou 310027, People’s Republic of China 5 Division of Physics and Applied Physics, School of Physical and Mathematical Sciences, Nanyang Technological University, Singapore 637371, Singapore E-mail: [email protected] and [email protected] New Journal of Physics 15 (2013) 113003 (14pp) Received 8 April 2013 Published 1 November 2013 Online at http://www.njp.org/ doi:10.1088/1367-2630/15/11/113003 Abstract. We demonstrate theoretically the existence of unidirectional surface plasmons in the nonreciprocal graphene-based gyrotropic interfaces. We show that a unidirectional frequency range is raised under a static external magnetic field where only one propagating direction is allowed for the surface plasmons mode. By efficiently controlling the chemical potential of graphene, the unidirectional working frequency can be continuously tunable from THz to near- infrared and even visible. Particularly, the unidirectional frequency bandwidth can be 1– 2 orders of magnitude larger than that in metal under the same magnetic field, which arises from the superiority of extremely small effective electron mass in graphene. Based on our theoretical analysis, two tunable graphene- based directional devices are proposed, showing the appealing properties of nonreciprocal graphene in the nonreciprocal optical devices design. 6 Authors to whom any correspondence should be addressed. Content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI. New Journal of Physics 15 (2013) 113003 1367-2630/13/113003+14$33.00 © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft 2 Surface plasmons originate from the collective excitations of electrons coupled to the electromagnetic field at the interface between dielectric and metal [1]. Their superb capability of confining electromagnetic energy at sub-wavelength scales [1] makes it possible to squeeze down current photonic components to ultracompact nanometer dimensions [1–7]. In particular, surface plasmons have been shown theoretically and experimentally to possess nonreciprocal properties in the presence of an external static magnetic field [8–15] similar to the chiral edge states of electrons in the quantum Hall effect [16–18]. For example, the heterostructure composed of magnetized metal film and two-dimensional (2D) photonic crystal [8, 9] possesses a unidirectional frequency range where only a forward propagating mode is allowed, with neither radiation nor backward modes, being immune from defects [8–10]. However, the previously observed nonreciprocity was generally weak and required a very large magnetic field. The design of unidirectional surface plasmons with a large frequency bandwidth under a modest magnetic field, hence, is in great demand for future applications in photonic isolators, diodes and logic circuits. Graphene [16–18], as a promising one-atom-thick photonic material where the doped electrons can be regarded as 2D electron gases (2DEGs), can support surface plasmons with widely tunable frequencies and reduced losses [19–24]. Recent advances in fabrication have enabled rapid progress in graphene plasmonics [25–34]. The photon–electron coupling in graphene is remarkably strong compared with that in metals (e.g. silver and gold) and 2DEGs in conventional semiconductors [19]. It mainly arises from both the extremely small effective electron mass at Fermi energy (i.e. cyclotron effective mass) meff [16–19, 35] and the efficiently tunable electrical gating in graphene [19]. In conventional 2DEGs, the 12 2 field induced 2D carrier density ns is limited to 1 10 cm− to avoid semiconductor ∼ × dielectric breakdown [19]. However, ns in graphene can be tuned by doping or gating from 10 2 14 2 very low (10 cm− ) to very high values (10 cm− )[19, 20, 36, 37]. Furthermore, meff 12 2 in graphene (meff 0.02m0 at ns 1 10 cm− , m0 is the mass of free electron [19]) is about two orders= of magnitude smaller= × than that of free electron in metal, and thus the integrated plasmon oscillator strength is correspondingly much larger [19]. These appealing properties of graphene have motivated extensive investigations in the emerging research field of graphene plasmonic and metamaterial devices [25–34], including optical sensors [38], photodetectors [39, 40], modulators [24, 41–43], waveguides [21, 22], antenna [44], lens [45, 46], Mach–Zehnder interferometers [47], cloaks [48], etc. Recently, significant experimental progress on unidirectional edge magnetoplasmons in a single graphene sheet was reported [33]. However, theoretical investigations on unidirectional surface plasmons in nonreciprocal graphene have been rarely discussed. In this paper, we present a theoretical study of nonreciprocal graphene and its applications to unidirectional surface plasmons. An externally applied static magnetic field B, which is assumed in the +z direction and perpendicular to the graphene plane (x–y plane), breaks the time-reversal symmetry in graphene and makes graphene gyrotropic. Two feasible waveguide structures, air/graphene single interface and air/graphene/dielectric double interfaces, are used for demonstration. The unidirectional frequency bandwidth is shown proportional to 1/meff, where meff is dependent on chemical potential µc in graphene. Hence, we show that even under a modest magnetic field ( B 0.1 T), graphene with small m is proven capable | | = eff of making the unidirectional frequency bandwidth very large. Moreover, by controlling µc, the unidirectional working frequency is widely tunable from terahertz (THz) to visible. Based on theoretical analysis, we proposed magnetic-field-controlled directional optical New Journal of Physics 15 (2013) 113003 (http://www.njp.org/) 3 components, indicating that nonreciprocal graphene can be a good candidate for future photonic device applications. We start by analyzing graphene’s optical properties. The complex optical conductivity in graphene (G Gintra + Ginter, where Gintra and Ginter are attributed to intra-band and inter-band transitions, respectively= [49, 50]) can be modeled by the Kubo formula [21, 48–50], ie2k T µ B c µc/kBT Gintra(ω, µc, τ, T ) 2 + 2 ln(e− + 1) , (1) = πh (ω + i/τ) kBT ¯ 2 ie (ω + i/τ) Z ∞ f ( E) f (E) G (ω, µ , τ, T ) d d dE, (2) inter c 2 − 2 − 2 = πh 0 (ω + i/τ) 4(E/h) ¯ − ¯ which relate to chemical potential µc, radian frequency ω, relaxation time τ and temperature T (assuming T 300 K in this work). E is the energy, e is electron charge, h is reduced Planck’s = (E µc)/kBT 1 ¯ constant, kB is Boltzmann’s constant and fd (E) (e − + 1)− is the Fermi–Dirac 2= 1 1 distribution. Since a DC mobility of µ > 100 000 cm V− s− has been experimentally achieved 2 1 1 in high-quality suspended graphene [17, 51] and µ > 60 000 cm V− s− in graphene on hexagonal boron nitride (h-BN) substrate was also reported [52], we can obtain τ > 1.8 ps by 2 6 1 using τ µcµ/(evF) [22] when setting µc 0.3 eV, where vF 0.95 10 m s− is the Fermi velocity.= To model one-atom-thick graphene= in macroscopic electromagnetic≈ × description, the graphene can be treated as an ultrathin film with thickness d 1 nm according to the previous work [19, 21, 22, 45]. Since the graphene carriers are well= localized within one-atom thick layer (x–y plane), the relative anisotropic permittivity in graphene [45] can be characterized as diag[εeqεeqεz], where εeq and εz are the components that are parallel and perpendicular to the graphene plane, respectively [45]. The equivalent complex permittivity εeq parallel to the graphene plane can be cast into the Drude form [19, 21, 22, 47, 53], 2 Gintra + Ginter Gintra ωp εeq 1 + i εinter + i εinter , (3) = ωε0d = ωε0d = − ω(ω + i/τ) where ε (1 + iG /ωε d) and ε is the dielectric permittivity in vacuum. Based on inter = inter 0 0 the macroscopic electromagnetic theory [53], the bulk plasma frequency is defined as ωp 2 1/2 = (Ne /m ε ) , where N ns/d is the bulk electron density. For an isolated graphene sheet, eff 0 = the 2D carrier density ns is determined by the chemical potential µc [49], 2 Z ∞ ns E[ fd (E) fd (E + 2µc)] dE. (4) 2 2 = πh v 0 − ¯ F From equations (1)–(4), both the bulk plasmon frequency ωp and the effective electron mass meff in graphene can be re-written as a function of chemical potential µc, e2k T µ 1/2 B c µc/kBT ωp 2 + 2 ln(e− + 1) , (5) = πh ε0d kBT ¯ 2 R ∞ v2 0 E[ fd (E) fd (E + 2µc)] dE F − meff . (6) µc/kBT = µc + 2kBT ln(e− + 1) 1/2 The relations between ns , meff, ωp and µc in graphene are shown in figure 1 through | | 1/2 equations (4)–(6).
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